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Harvesting Energy From Radio Waves to Power Wearable Electronic Devices

An international team of researchers, led by Huanyu “Larry” Cheng, Dorothy Quiggle Career Development Professor in the Penn State Department of Engineering Science and Mechanics, has developed a stretchable antenna and rectenna system that harvests energy from radio waves in the ambient environment to power wearable devices. Credit: Larry Cheng, Penn State

From microwave ovens to Wi-Fi connections, the radio waves that permeate the environment are not just signals of energy consumed but are also sources of energy themselves. An international team of researchers, led by Huanyu “Larry” Cheng, Dorothy Quiggle Career Development Professor in the Penn State Department of Engineering Science and Mechanics, has developed a way to harvest energy from radio waves to power wearable devices.

The researchers recently published their method in Materials Today Physics.

According to Cheng, current energy sources for wearable health-monitoring devices have their place in powering sensor devices, but each has its setbacks. Solar power, for example, can only harvest energy when exposed to the sun. A self-powered triboelectric device can only harvest energy when the body is in motion.

“We don’t want to replace any of these current power sources,” Cheng said. “We are trying to provide additional, consistent energy.”

The researchers developed a stretchable wideband dipole antenna system capable of wirelessly transmitting data that is collected from health-monitoring sensors. The system consists of two stretchable metal antennas integrated onto conductive graphene material with a metal coating. The wideband design of the system allows it to retain its frequency functions even when stretched, bent and twisted. This system is then connected to a stretchable rectifying circuit, creating a rectified antenna, or “rectenna,” capable of converting energy from electromagnetic waves into electricity. This electricity can be used to power wireless devices or to charge energy storage devices, such as batteries and supercapacitors.

This rectenna can convert radio, or electromagnetic, waves from the ambient environment into energy to power the sensing modules on the device, which track temperature, hydration and pulse oxygen level. Compared to other sources, less energy is produced, but the system can generate power continuously — a significant advantage, according to Cheng.

“We are utilizing the energy that already surrounds us — radio waves are everywhere, all the time,” Cheng said. “If we don’t use this energy found in the ambient environment, it is simply wasted. We can harvest this energy and rectify it into power.”

Cheng said that this technology is a building block for him and his team. Combining it with their novel wireless transmissible data device will provide a critical component that will work with the team’s existing sensor modules.

“Our next steps will be exploring miniaturized versions of these circuits and working on developing the stretchability of the rectifier,” Cheng said. “This is a platform where we can easily combine and apply this technology with other modules that we have created in the past. It is easily extended or adapted for other applications, and we plan to explore those opportunities.”

Reference: “Stretchable wideband dipole antennas and rectennas for RF energy harvesting” by
Jia Zhu, Zhihui Hu, Chaoyun Song, Ning Yi, Zhaozheng Yu, Zhendong Liu, Shangbin Liu, Mengjun Wang, Michael Gregory Dexheimer, Jian Yang and Huanyu Cheng, 5 March 2021, Materials Today Physics.

This paper is co-authored by Jia Zhu, who earned a doctoral degree in engineering science and mechanics from Penn State in 2020; Zhihui Hu, former visiting professor in engineering science and mechanics at Penn State and current associate professor at Wuhan University of Technology in China; Chaoyun Song, assistant professor in the School of Engineering and Physical Sciences at Heriot-Watt University in Scotland; Ning Yi, who earned a doctoral degree in engineering science and mechanics from Penn State in 2020; Zhaozheng Yu, who earned a master’s degree in engineering science and mechanics from Penn State in 2019; Zhendong Liu, former visiting graduate student in engineering science and mechanics at Penn State; Shangbin Liu, graduate student in engineering science and mechanics at Penn State; Mengjun Wang, associate professor in the School of Electronics and Information?Engineering at Hebei University of Technology in China; Michael Gregory Dexheimer, who earned a master’s degree in engineering science and mechanics from Penn State in 2020; and Jian Yang, professor of biomedical engineering at Penn State.

Support for this work was provided by the National Science Foundation; the National Heart, Lung, and Blood Institute of the National Institutes of Health; and Penn State.

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